Review of the rodent paleoparasitological knowledge from South America

Quaternary International xxx (2014) 1e7

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Review of the rodent paleoparasitological knowledge from South America ^ nica Vieira de Souza b, Adauto Araújo b, María Ornela Beltrame a, *, Mo  Sardella a Norma Haydee a

Laboratorio de Paleoparasitología y Arqueología Contextual, Departamento de Biología, Facultad de Ciencias Exactas y Naturales, Universidad Nacional de Mar del Plata, Funes 3250, 7600 Mar del Plata, Consejo Nacional de Investigaciones Científicas y T ecnicas (CONICET), Buenos Aires, Argentina rio de Paleoparasitologia, Escola Nacional de Saúde Pública S ~es 1480, 21041-210, Rio de Janeiro, Laborato ergio Arouca-Fiocruz, Rua Leopoldo Bulho RJ, Brazil

b

a r t i c l e i n f o

a b s t r a c t

Article history: Available online xxx

Rodents (Mammalia, Rodentia) are a key mammalian group with a worldwide distribution. The relevance of rodents as hosts in parasitic life-cycles, also in those of zoonotic impact, has been fully recognized. Parasites have been found in ancient remains throughout the world. Paleoparasitology is the study of ancient parasites recovered from archaeological and paleontological sites and materials. This paper reviews the major research activities carried out in rodent paleoparasitology from South America, aiming to integrate data and generate prospects in this field of research. The presence of rodent parasites in ancient times can provide useful and valuable information, as rodent paleoparasitological data can be used from diverse point of views. Anthropologists, biologists, archaeologists, and paleontologists can use this data to reconstruct ancient events based on the parasite life cycles and on the biological requirements to maintain the transmission from host to host. Rodent paleoparasitology may provide a picture of the biodiversity of parasites in ancient times. Although rodent remains are generally present in ancient times, their recovery from archaeological and paleontological contexts is still exceptional. © 2014 Elsevier Ltd and INQUA. All rights reserved.

Keywords: Rodents Paleoparasitology South America

1. Introduction Rodents (Mammalia, Rodentia) are a key mammalian group with a worldwide distribution, over 42% of all mammal species (Carleton and Musser, 2005). Their success is due to their small size, the short pregnancy and the ability to gnaw and to eat a wide variety of foods (Wilson and Reeder, 2005). Rodents are important in many ecosystems because they reproduce rapidly, and can function as food source for predators, as dispersors of seeds and as vectors of diseases. Some species are good ecological, climatological, and ndez geographical indicators (i.e. Legendre et al., 2005; Herna ndez, 2006; Smith, 2012). Ferna The relevance of rodents as hosts in parasitic life-cycles, also in those of zoonotic impact, has been fully recognized (Miyazaki, 1991; Perkins et al., 2005; Morand et al., 2006). Their role as reservoirs of zoonoses has long been known. Rodents are hosts to a number of ectoparasites such as lice, mites, and ticks, and can

* Corresponding author. E-mail addresses: [email protected], (M.O. Beltrame).

[email protected]

transmit viral, bacterial and protozoan parasites to humans and animals (Soliman et al., 2001). In addition, they can harbour many different protozoan and helmintic endoparasites (Morand et al., 2006). Parasites have been found in ancient remains throughout the world (Reinhard, 1990; Bouchet et al., 2003; Gonçalves Carvalho et al., 2003; Araújo et al., 2011). Paleoparasitology is the study of ancient parasites recovered from archaeological and paleontological sites and materials (Ferreira et al., 1979; Gonçalves Carvalho et al., 2003). It aims to provide additional information on parasites themselves (origin, history, evolution), on human and animal populations (paleopathology, sanitary conditions, lifestyles), and also on relationships among hosts, parasites and their environment (Reinhard, 1992; Bouchet et al., 2003; Le Bailly and Bouchet, 2010, 2013). At the end of the 1980s, paleoparasitology added rodents as important material to be studied. The first research started on coprolites of the Brazilian endemic rodent Kerodon rupestris (Rodentia, Caviidae). Eggs and larvae of Strongyloides ferreirai and eggs of Trichuris sp. (roundworms, nematodes) were found in samples collected from archaeological layers dated from 8000 to 2000 BP from Brazil (Araújo et al., 1989). This paper reviews the

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major research activities carried out in rodent paleoparasitology from South America, aiming to integrate data and generate prospects in this field of research. 2. Sources and techniques used in ancient rodent parasitic studies In some paleontological and archaeological sites from South America, coprolites are the most common source of paleoparasitological data. In southern Patagonia and Northeasthern Brazil, coprolites are generally found by archaeologists and paleontologists dispersed in layers from rock-shelters and caves. The study of coprolites presents some difficulties. When coprolites are collected from mummified bodies, their origin is clear. Commonly, coprolites are found free in sediment layers of archaeological and paleontological sites. The identification of the biological origin of the coprolites is mainly based on the knowledge of the feces of the local fauna and on morphometric characteristics associated with macro and microscopic examination (Chame, 2003). In the 2000s, the study of raptor pellets and sediments opened up the possibility of new ancient rodent parasite sources of evidence (Fugassa, 2006a; Fugassa et al., 2007). Raptor pellets collected from archaeological sites are considered as good rodent material for parasitic studies (Beltrame et al., 2011). Mummified bodies are rarely found in Brazilian and Argentinian archaeological sites. However, human and other animal mummies were recovered from archaeological sites from Perú. This allowed ectoparasite studies in rodent paleoparasitological data. The examination of mummies of the Guinea pig Cavia porcellus (Rodentia:

Caviidae) from Perú enabled the recognition of mites, fleas, and lice from ancient samples (Dittmar, 2000). Rodent organic remains are examined by parasitological regular techniques after rehydration using a trissodium phosphate aqueous solution 0.5% (Na3PO
4 ) for 72 h (Callen and Cameron, 1960). Next, spontaneous sedimentation is recommended (Lutz, 1919; Araújo et al., 1998). Technical improvements in Polymerase Chain Reaction (PCR) analysis added the possibility of studies with ancient DNA. Mitton (2012) achieved molecular detection of Trichuris spp. from samples of rodent coprolites from an archaeological site from Argentina from one egg. This technique has been also used with different tissues, offering a great spectrum of research for infectious diseases from archaeological samples. Bastos et al. (1996) used PCR to study the kinetoplast DNA (kDNA) of Chagas disease, Trypanosoma cruzi, from experimentally desiccated mouse tissue (heart, skeletal, muscle, spleen, and pancreas). The preliminary data suggest the application of this technique to detect T. cruzi in archaeological rodent material. On the other hand, the protozoan causative of toxoplasmosis (Toxoplasma) has not yet been detected in ancient remains, although successful recovery of its DNA has been accomplished from desiccated mousse tissues (Terra et al., 2004). The application of PCR to rodent paleoparasitological toxoplasmosis and Chagas disease research is a promising option. 3. Studies of ancient rodent parasites from South America Records of ecto and endoparasites recovered from rodents from archaeological and paleontological sites of South America have been published chronologically (Table 1).

Table 1 Summary of South America rodent paleoparasitological findings. Locality

Date (yr B.P.)

Sample

Host

Parasites

Measurements (mm)

References

Piauí, Brazil

8000e2000

Coprolites

Kerodon rupestris

61.96  31.65 (N ¼ 10)

Pedra Furada, Brazil

30,000e8450

Coprolites

K. rupestris

Strongyloides ferreirai Trichuris sp. Trichuris

60e65  30e33

Sitio do Meio, Piauí, Brazil

9000 yr

Coprolites

K. rupestris

Trichuris sp.

59e66  33 (N ¼ 20)

El Yaral, Moquegua Valley, Perú

Chiribaya Culture Mummies

Cavia porcellus (guinea pigs)

Orejas de Burro 1, Santa Cruz, Argentina n, Chubut, Alero Mazquiara Argentina

3720e3978

Trimenopon hispidum, Gliricola porcelli. Ornithonyssus spp. Pulex simulans Eimeria macusaniensis

Araújo et al. (1989) Ferreira et al. (1991) Araújo et al. (1993) Dittmar (2000)

s. XIX

Rodent Unidentified coprolites Coprolites Unidentified and sediments

Cerro Casa de Piedra, Santa Cruz, 6540 ± 110 Argentina Cerro Casa de Piedra 7, Santa Cruz, 7920 ± 130 Argentina

Raptor pellet

Unidentified

Coprolites

Ctenomys sp.

n, Chubut, Alero Mazquiara Argentina

Coprolites

Unidentified

212 ± 35

Alero Destacamento Guardaparque, 6700 ± Santa Cruz, Argentina 70e3440 ± 70

Cerro Casa de Piedra, Santa Cruz, Argentina

2740 ± 100e3.990 ± 80

CCP 7

10,620 ± 40e9390 ± 40

Coprolites

Raptor pellets Abrothrix sp. and Euneomys chinchilloides Coprolites Species of Caviomorpha Coprolites Lagidium viscacia

Anoplocephalid Trichuris sp. Ascaridid Capillaria sp. Capillaria sp.

55e60  57.5e61.25 (N ¼ 4) 66.25  52.5 53  35 65  35 37.5e42.5  63.75e68.75

Trichuris sp. Paraspidodera uncinata Eucoleus sp. Monoecocestus sp. Pterygodermatites sp. Trichosomoides sp. Trichuris sp. Calodium sp. Eucoleus sp. Echinocoleus sp. Monoecocestus sp. Calodium sp. Trichuris sp. taeniid Heteroxynema sp. Trichuris sp.

60e67.5  30e37.5 57.5e67.5  45e50 (N ¼ 24) 60e62.5  37.5e40 50e62.5  50e62.5 (N ¼ 30) 65e75  45e52.5 (N ¼ 13) 62.5  62.5 (N ¼ 5) 57.5e70  30e35 57.5e70  33.75e47.5 50e55  22.5e35 (N ¼ 85) 65  31.5 (N ¼ 1) 48,75e70  47.5e70 39.8 ± 2.2  67.2 ± 3.8 (N ¼ 60) 60  35 (N ¼ 1) 37.5  33.5 (N ¼ 1) 87.5e107.5  45e62.5 (N ¼ 30) 67.5e77.5  40e45 (N ¼ 96)

Fugassa and Barberena (2006) Fugassa (2006b)

Fugassa et al. (2007) Sardella and Fugassa (2009a) Sardella and Fugassa (2009b) Sardella et al. (2010)

Beltrame et al. (2011) Sardella and Fugassa (2011)

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M.O. Beltrame et al. / Quaternary International xxx (2014) 1e7

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Table 1 (continued ) Locality

Date (yr B.P.)

n, Cueva Huenul 1, Neuque Argentina

13,844 ± 75e1416 ± 37

Toca dos Coqueiros, National Park of Serra da Capivara, Brazil Cueva Huenul 1 and Perfil los Altares, Argentina Los Altares Profile, Chubut, Argentina

5300 ± 50

13,844 ± 75 to present

Sample

Measurements (mm)

Host

Parasites

Coprolites

K. rupestris

Heteroxynema viscaciae 133.39 ± 4.10  62.75 ± 4.48 Viscachataenia quadrata (N ¼ 90) 82.69 ± 5.44  91.73 ± 8.74 Monoecocestus sp. (N ¼ 13) 59.15 ± 1.3  56.7 ± 1.5 (N ¼ 4) Syphacia sp. 101  35.7 (N ¼ 1)

Coprolites

L. viscacia

2210 ± 70 yr B.P. Coprolites to present

Unidentified anoplocephalid

L. viscacia and Heteroxynema viscaciae Microcavia australis Helminthoxys sp. Anoplocephalid 1 Anoplocephalid 2 Anoplocephalid 3

With respect to the endoparasites, the first paper referring to ancient rodent parasites dates from 1989, when Araújo et al. published the discovery of eggs and larvae of S. ferreirai (Nematoda: Strongylidae), and eggs of Trichuris sp. (Nematoda: Trichuridae) in coprolites of K. rupestris collected from archaeological sites from Piauí State, northeast Brazil (Araújo et al., 1989). K. rupestris is an endemic rodent living in rocky areas of Brazil. Coprolites were dated from 8000 to 2000 BP and were identified by comparison with recent feces of K. rupestris. The authors suggested that the species that were found could be a new or a known species of Trichuris, not yet described in this host. This paper stated that the parasitic fauna of South American wild animals is not completely studied, and new species of parasites can be found by examination of ancient material. The second contribution was made when Ferreira et al. (1991) recovered eggs of Trichuris from coprolites of K. rupestris collected from Pedra Furada, Piauí State, northeast Brazil, from archaeological layers dated from 30,000 to 8450 BP. Moreover, more than 1000 fresh pellets from K. rupestris collected in their specific sites of defecation on the rocks were examined and were negative for Trichuris. This report suggests the existence of an unknown species of Trichuris parasitizing K. rupestris in the period from at least 30,000 to 8000 BP. The authors discuss the climatic changes that could be present in the region and the antiquity of the hosteparasite relationships. Araújo et al. (1993) also found eggs of Trichuris spp. in coprolites of K. rupestris dated at 9000 yrs B.P. collected in archaeological sites ~o Raimundo Nonato, Piauí State, northeast Brazil. However, of Sa present day local rodents seem not to be infected by this parasite, suggesting its disappearance due to climatic changes. The first study on rodents in Argentina was Fugassa and Barberena (2006) with the examination of sediments from the archaeological site “Orejas de Burro 1”, Santa Cruz province. The site consists of a multiple burial and archaeological levels with evidence of human activity. The burial was dated at 3720e3978 BP. Sediments from one human skeleton were examined for parasites and the macroscopic examination revealed the presence of rodent coprolites. These coprolites were negative for parasite eggs, but the protozoan Eimeria macusaniensis (Apicomplexa: Eimeriidae) oocysts were found. The authors discuss the presence of parasites as a source of information about the ecology of the human groups that occupied the cave, and ancient zoonoses. E. macusaniensis is a camelid parasite, probably found in the rodent coprolite due to contamination. Sediments proceeding from the pelvic cavity of human and associated rodent coprolites from the archaeological site “Alero Mazquiar an”, Chubut Province, Argentina, were examined for

60e87  60e87 (N ¼ 31)

References Beltrame et al. (2012)

Vieira de Souza et al. (2012) Beltrame et al. (2013)

Beltrame et al. 120e135  57.5e67.5 (N ¼ 7) 77.5e92.5  45.0e52.5 (N ¼ 17) (2014) 67.5e87  62.5e87 (N ¼ 25) 80e92.5  70e87.5 (N ¼ 15) 67.5  57.5 (N ¼ 1)

parasites, a rockshelter associated with the European contact, probably 19th century. Eggs of anoplocephalids platyhelminthes (flatworms), and the nematodes Trichuris sp., unidentified ascaridid and Capillaria sp. (Nematoda: Capillariidae) were found (Fugassa, 2006b). The author discusses the probable contamination of sediments with rodent parasites. Fugassa et al. (2007) reported the first study on regurgitated pellet belonging to a bird of prey from the archaeological site “Cerro Casa de Piedra” (CCP), Perito Moreno National Park, Santa Cruz Province, Argentina. CCP is a hill of volcanic origin, with a set of caves and rockshelters. Sample was dated at 6540 ± 110 BP. Microscopic examination revealed the presence of eggs of Capillaria sp. attributed to a rodent ingested by the bird. Rodent hairs and a mite, Demodex sp., were also found. The author stated that pellets may provide a parasitological record of prey. Rodent coprolites from CCP with an antiquity considered as 7920 ± 130 BP were also examined (Sardella and Fugassa, 2009a). In this case, all samples were parasitized by nematodes: eggs of Trichuris sp. (Trichuridae), Paraspidodera uncinata (Aspidoderidae) and Eucoleus sp. (Capillariidae). Based on the macroscopical aspect of the feces and on the paleoparasitological results, coprolites were assigned to the South American endemic octodontid rodent Ctenomys, “tuco-tuco”. The first finding of Paraspidodera in Patagonian samples is discussed. This finding represents new evidence that strengthens the co-phylogenies between nematodes of this genus and Ctenomys, and discusses the value of parasites as tags in paleoparasitology. Samples from the archaeological site “Alero Mazquiar an”, Chubut Province, Argentina, were also examined for parasites (Sardella and Fugassa, 2009b). This site is a rockshelter assigned to the interface of the Araucanian and Tehuelche cultures, dated at 212 ± 35 BP. Rodent coprolites were positive for eggs of the flatworms Monoecocestus sp. (Cestoda: Anoplocephalidae), Pterygodermatites sp. (Nematoda: Rictulariidae), and Trichosomoides sp. (Nematoda: Trichosomoididae). In this study, the authors discuss the parasitic life cycles, the zoonotic importance of parasites, and the behavior of the aboriginal people. Sardella et al. (2010) examined rodent coprolites from the archaeological site “Alero Destacamento Guardaparque” (ADG), Perito Moreno National Park, close to CCP. Coprolites were dated at 6700 ± 70e3440 ± 70 BP. A total of 582 parasite eggs were found in 47 coprolites. Parasites species were the roundworms Trichuris sp., Calodium sp., Eucoleus sp., Echinocoleus sp. and an unidentified capillariid (Nematoda: Capillariidae), and eggs of Monocoecestus sp. In this study, the specific affiliations of parasites, their zoonotic

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importance, the rodent identity, on the basis of previous zooarchaeological knowledge, and the environmental conditions during the Holocene in the area are discussed. Sardella and Fugassa (2011) also examined rodent coprolites from another layers of CCP dated at 10,620 ± 40e9390 ± 40 BP. Eggs of the oxyurid nematode Heteroxynema sp. (Cavioxyura sp.) (Nematoda: Heteroxynematidae) and Trichuris sp. were observed. The rodent was identified as an unknown species of Caviomorpha (Hystricognathi) that lived during the Pleistocene transition in Patagonia. Heteroxynema sp. is cited for the first time from ancient material. The authors discuss the finding of Trichuris and its relationships with environmental conditions. The second contribution on raptor pellets was made by Beltrame et al. (2011). Samples come from CCP and were dated at 2740 ± 100 and 3990 ± 80 BP. It was possible to identify the rodent contents (bones and teeth) in the pellets. Rodents were identified as the cricetids Abrothrix sp. and Euneomys chinchilloides. Eggs of two nematodes Trichuris sp. and Calodium sp., and one taeniid cestode were found. This study increases the evidence that raptor pellets can be used as source of paleoparasitological information in archaeological sites. The authors also discuss the role of rodents as causative of possible zoonoses in ancient times. n The archaeological site “Cueva Huenul 1” (CH1), Neuque Province, Argentina, was also studied for ancient rodent parasites. This is an archaeological cave that provides stratified sequences of archaeological and paleontological remains assigned from the Late Pleistocene/Early Holocene Transition to the Late Holocene period. Beltrame et al. (2012) examined rodent coprolites dated from 13,844 ± 75 to 1416 ± 37 BP. Feces were positive for the flatworms Viscachataenia quadrata and Monoecocestus sp. (Cestoda: Anoplocephalidae), and for the roundworm Heteroxynema (Cavioxyura) viscaciae (Nematoda: Oxyuridae). The coprolites examined were attributed to Lagidium viscacia (Rodentia, Caviomorpha, Chin n”. The life cycles of chillidae), called “vizcacha serrana or chinchillo these parasites was also discussed. Paleoparasitological studies on coprolites of K. rupestris were also conducted by Vieira de Souza et al. (2012) in Brazil. Coprolites were collected from excavations at the archaeological site “Toca dos Coqueiros”, from Serra da Capivara National Park. Coprolites were dated at 5300 ± 50 BP, and Syphacia eggs (Nematoda: Oxyuridae) were identified. The authors discuss this finding in ancient samples. Eggs with morphological features attributed to an anoplocephalid cestode, Andrya or Monocoecestus, were found in samples collected from the archaeological site CH1 and from the paleontological site “Los Altares Profile” (LAP), Chubut Province, Argentina. It corresponds to an accumulation of sedimentary fill remnant of an ancient cave eliminated by road works, dated to Late Holocene. Coprolites were identified as belonged to L. viscacia and were compared with current feces of this rodent, where similar anoplocephalid eggs were found. These are the first findings of this anoplocephalid from faecal material from patagonic rodents (Beltrame et al., 2013). The authors discuss their life cycles and the importance of this kind of study. Finally, other rodent coprolites from LAP were studied for parasites (Beltrame et al., in this issue). Samples were positive for eggs of Heteroxynema (Cavioxyura) viscaciae, for an unidentified oxyurid (attributed to Helminthoxys) (Nematoda: Oxyuridae), and for anoplocephalids with features of 3 morphotypes. Coprolites were dated at 2210 ± 70 BP to present. Some of the rodent hosts were tentatively identified as Microcavia australis (Caviomorpha:Caviidae), the southern mountain cavy of South America, and others were attributed to L. viscacia, based on their morphology and the parasites found. Respect to the ectoparasites recovered from ancient samples, the only reference is those of Dittmar (2000). Guinea pig (C.

porcellus) mummies were excavated at the archeological site “El Yaral”, Moquegua Valley, Southern Peru. It belongs to a complex of settlements dated to the coastal Chiribaya Culture. Thirty-two of the 112 studied guinea pigs were positive for arthropod parasitic remains: the lice Trimenopon hispidum and Gliricola porcelli (Mallophaga), mites of Ornithonyssus spp., and the flea Pulex simulans (Siphonaptera). Parasitic infestations of domestic livestock have always been a problem, not only involving the domesticated animals if not the human population to which they are associated. The author also discusses the health aspects of the presence of ectoparasites on humans and animals. 4. Information provided by ancient rodent parasites The presence of rodent parasites in ancient times can provide useful and valuable information, as rodent paleoparasitological data can be used from diverse points of view. Anthropologists, biologists, archaeologists, and paleontologists can use this data to reconstruct ancient events based on the parasite life cycles and on the biological requirements to maintain the transmission from host to host. Rodent paleoparasitology may provide a picture of the biodiversity of parasites in ancient times. This review shows a wide diversity of rodent parasites collected from ancient sites studied in South America (Table 1). These findings are possible because caves and rockshelters are excellent sites of preservation of samples and parasitic remains. With respect to nematodes, Trichuris spp. includes intestinal parasites of the caecum and colon of mammals, mainly humans, primates, pigs, ovines, goats, cervids, rodents, lagomorphs, African antelopes, marsupials, felids, and canids. They hatch in the small intestine of the definitive host and larvae migrate to the large intestine, where they reach the adult stage (Anderson, 2000). They act as geohelmints because infection involves ingestions of contaminated soils, and they also require climatic conditions in the soil to maintain infections inside the host. Consequently, climate aspects can be inferred when these parasites are found in archeological sites (Araújo et al., 1993). There are reports of the findings of Trichuris spp. from K. rupestris from Brazil from at least 30,000 BP (Araújo et al., 1989, 1993; Ferreira et al., 1991). Nevertheless, coprolites of K. rupestris with more recent dating, from at least 400 years ago, were also positive for Trichuris sp. (Sianto, 2009; Vieira de Souza, 2013) as were samples collected in more humid regions of the Brazilian semiarid (Sianto et al., 2006). There are also reports of Trichuris from archaeological sites of Argentina from at least 8000 BP (Fugassa, 2006b; Sardella and Fugassa, 2009a, 2011; Sardella et al., 2010; Beltrame et al., 2011) and they continue today (Suriano and Navone, 1994; Rossin and Malizia, 2005; among others). Climate changes 10,000 years ago in the region could be the cause of the disappearance of Trichuris from Brazil. However, this helminth is found in the region today. Cestodes are a ubiquitous group of intestinal and tissue parasites of all vertebrates, and are currently found in small mammals (Morand et al., 2006). The Anoplocephaline cestodes (Cyclophyllidea: Anoplocephalidae) represent a diverse group of parasites infecting both terrestrial mammals (placentals and marsupials) and birds from all major zoogeographic regions; however they are not commonly found from Central and South America (except for species of Monoecocestus). The most important radiation of anoplocephalines has been displayed in rodents and lagomorphs € m et al., 2005). Intermediate hosts are (Beveridge, 1994; Wickstro oribatid mites ingested by their herbivorous definitive hosts (Beveridge, 1994). Parasites transmitted by arthropod vectors are restricted to the distribution area where the parasite and the arthropod are in close contact with the host. This implies that

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M.O. Beltrame et al. / Quaternary International xxx (2014) 1e7

parasite distribution is limited by favorable environmental conditions for the vector life cycle. Therefore, the presence of anoplocephalids in ancient samples can also provide information on the paleoenvironmental conditions in the period under study and on the local fauna. Paleoparasitology should be combined with zooarchaeology in order to extend the information concerning rodent parasites. Another case that may be mentioned in this regard is Spirurina, which include a diverse group of nematodes that use intermediate hosts such as arthropods, insects, and crustaceans. Eggs of the genus Pterigodermatites were found in ancient samples from Alero Mazquiar an, and this finding represents the first worldwide (Sardella and Fugassa, 2009a). Anoplocephalid cestodes were found in some archaeological sites from Patagonia, Argentina. Eggs of V. quadrata, Monoecocestus spp. and two unidentified anoplocephalids were found from samples examined (Fugassa, 2006b; Sardella and Fugassa, 2009b; Sardella et al., 2010; Beltrame et al., 2012, 2013, 2014). Anoplocephalid species are very difficult to identify from their eggs. Uterine morphology has played a key role in systematic and phylogenetic arrangements within this group. Eggs are not often taken into account at present to determine taxonomic differences among genera. Nevertheless, the importance of the study of anoplocephalid eggs is evident in paleoparasitological studies. Eggs are the most commonly parasitic remains found in coprolites, and generally are unique. It is necessary to improve the published descriptions and illustrations of eggs in most of the future taxonomic studies. This point is fundamental for future identifications not only of anoplocephalids, but also of all representative rodent parasites. Species of oxyurid nematodes are monoxenic parasites that live in the digestive tract of various vertebrates and arthropods (Anderson, 2000). Oxyuroidea from vertebrates can be grouped into 3 families: Pharyngodonidae, Oxyuridae, and Heteroxynematidae (Petter and Quentin, 2009). Heteroxynematidae includes nematodes that evolved in sciuromorph, caviomorph, and miomorph mammals. Heteroxynema spp. was found in coprolites dated at 10,620 ± 40e9390 ± 40 BP belonging to an unknown species of Caviomorpha (Hystricognathi) from CCP (Sardella and Fugassa, 2011). Heteroxynema viscaciae (Heteroxynematidae) is a parasite found in the caecum and large intestine from L. viscacia from Chubut Province, Argentina: it was first described by Hugot and Sutton (1989). H. viscaciae was also found in ancient coprolites assigned to L. viscacia from CH1 (Beltrame et al., 2012) and from the paleontological site LAP (Beltrame et al., in this issue). In these studies, the presence of these eggs allowed the identification of the biological origin of the coprolites due to the specificity of this species. This is another interesting contribution of the study of the rodent parasite eggs. In some archaeological and paleontological studies, is impossible to do the coprolite identification solely using their morphology. However, the knowledge of the local fauna and the paleoparasitological study can contribute to the rodent host identification. Members of the genus Syphacia (Oxyuridae: Syphaciinae) are cosmopolitan and are frequently found in the caecum of rodents and lagomorphs (Hugot, 1988). This genus includes more than 60 species, of the around 20 species known from North and South America (Hugot, 1988; Vicente et al., 1997; Robles and Navone, 2007a, b; Robles et al., 2008). Species of Syphacia generally exhibit a co-evolutionary relationship with their hosts, with each Syphacia species showing specificity with the host genus (Hugot, 1988; Robles, 2010). Eggs of Syphacia were found in K. rupestris coprolites from Brazil, dated at 5300 BP (Vieira de Souza et al., 2012). Future studies on rodent coprolites can contribute to the

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knowledge of the evolutionary patterns of Syphacia with their hosts. Nematodes of the family Aspidoderidae parasitize hystricognath rodents. Paraspidodera uncinata was found in rodent coprolites from CCP. Species of Paraspidodera exhibit a high specificity for octodontid rodents of the genus Ctenomys in which they are usually present in high densities. Paraspidodera uncinata occupies a wide geographic range (Sardella and Fugassa, 2009a). Based on the macroscopical aspect of the feces and on the paleoparasitological results, coprolites were assigned to the South American endemic octodontid rodent of the genus Ctenomys. The finding of P. uncinata in Patagonian ancient samples extends its geographic range. This record also constitutes the first time this parasite species has been found in old material and represents new evidence that strengthens the co-phylogenies between Paraspidodera and Ctenomys, as proposed by Gardner (1991). The finding of rodent parasites in ancient material can show the antiquity of the hosteparasite relationships and in some, of the parasite losses through time. The parasitic fauna of South American wild animals is not completely studied. From the study of ancient material, new species of parasites can be found in archaeological and paleontological sites. Another species cited for the first time from old and also for new material in Argentina is Trichosomoides crassicauda. It is a parasite of the rodent urinary system. Sardella and Fugassa (2009a) found this parasite in rodent coprolites from Alero n. Mazquiara Rodents represent one of the most important sources of zoonoses for mammals, and their increasing density forced their dispersion to occur and brought them into closer contact with humans (Perkins et al., 2005). Anoplocephalids are parasites of zoonotic importance for animals and humans (Denegri et al., 1998). It is known that Pterigodermatites is parathenic in carnivores, with evidence of disease in humans (Anderson, 2000). Some species of the Capillaridae are also zoonotic. Capillarids were present at several sites (Fugassa, 2006b; Fugassa et al., 2007; Sardella and Fugassa, 2009a; Sardella et al., 2010; Beltrame et al., 2011). Dittmar (2000) found ectoparasites in mummies of guinea pigs. Ectoparasites are parasites of zoonotic importance and also are vectors of zoonotic pathogens. The presence of zoonotic parasites can show that humans and other animals living in archaeological sites studied were exposed to parasitic zoonoses. Remains of rodents have been noted in human coprolites throughout history, and provide direct evidence of animal consumption (Reinhard et al., 2007). Rodent parasitic studies added to the archaeological studies can contribute to the knowledge of illness in ancient times. This review suggests that the sites under study, caves and shelters, could act as suitable environments for transmission of various types of parasites. Additional studies on zoonotic infections from the past will expand the knowledge on biological aspects of the health-disease processes and the co-evolution among parasites, animals, and human hosts. Rodent bones are commonly found in archaeological and paleontological sites. Associated materials such as sediments and coprolites are an important source for paleoparasitological research. Results summarized in this review encourage archaeologists and paleontologists to recover coprolites and other possible sources of rodent parasite remains, because of the relevant information available. Raptor pellets can be used as a source of paleoparasitological information (Beltrame et al., 2011). Pellets provide evidence of less digestible remains of their prey, such as scales, feathers, teeth, hair, and bones, most likely of rodent origin (Marti, 1987). Remains allowed recognition of the host in most cases.

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Mummies are representatives of ancient populations and lives throughout the world (Bouchet et al., 2003). Parasite eggs and larvae found in mummy intestinal contents can be more easily identified than those found in coprolites or sediments. With mummies, the host is immediately known. As any other organic remain, mummified bodies may be found in any archaeological region. Rodent mummified bodies can be an important source for paleoparasitological data and should be studied in future research. Advances in the knowledge of the parasitism in rodents require continuing with the implementation of new techniques, mainly the molecular techniques, in order to extend the study of the parasitism itself, as well as to identify the biological origin of samples, that without doubt will broad the interpretation of the results concerned with ancient materials. 5. Conclusions As evidenced by the rodent paleoparasitological findings summarized above, an interesting paleoparasitological picture has been traced from South America archaeological and paleontological studied sites. Paleoparasitological research has increased over time and has made important contributions in several aspects. Although rodent remains are generally present in ancient times, their recovery from archaeological and paleontological contexts is still exceptional. As more materials and more sensitive techniques become available, as detection of parasite DNA and immunological antigen detection improves, more parasitic indicatives of ancient infections will be detected. Acknowledgments We appreciate the comments of reviewer Karl Reinhard, which were included in the final revision of the manuscript. References Anderson, R.C., 2000. Nematode Parasites of Vertebrates: Their Development and Transmission. CAB International, Wallingford, UK, 650 pp. Araújo, A., Ferreira, L.F., Confalonieri, U., Chame, M., Ribeiro, B., 1989. Strongyloides ferreirai Rodrigues, Vicente and Gomez, 1985 (Nematoda, Rhabdiasoidea) in rodent coprolites (8.000e2.000 years BP), from archaeological sites from Piauí,  rias do Instituto Oswaldo Cruz 84 (4), 493e496. Brazil. Memo Araújo, A., Rangel, A., Ferreira, L.F., 1993. Climatic change in northeastern Brazil e rias do Instituto Oswaldo Cruz 88 (4), 577e579. Paleoparasitological data. Memo ~ ighez, A., Vicente, A.C., Araújo, A., Reinhard, K., Bastos, O.M., Costa, L.C., Pirmez, C., In Morel, C.M., Ferreira, L.F., 1998. Paleoparasitology: perspectives with new techniques. Revista do Instituto de Medicina Tropical de S~ ao Paulo 40 (6). Retrieved June 24, 2014, from. http://www.scielo.br/scielo.php. ~ iguez, A., Fugassa, M., Arriaza, B., Araújo, A., Reinhard, K., Leles, D., Sianto, L., In Orellana, N., Ferreira, L.F., 2011. Paleoepidemiology of intestinal parasites and lice in pre-columbian South America. Chungar a 43, 303e313. Bastos, O.M., Araújo, A., Ferreira, L.F., Santoro, A., Wincker, P., Morel, C.M., 1996. Experimental paleoparasitology: Identification of Trypanosoma cruzi DNA in dessicated mousse tissue. Paleophatology Newsletter 5 (94), 5e8. Beltrame, M.O., Fugassa, M.H., Sardella, N.H., Civalero, M.T., Aschero, C., 2011. Raptor pellets as zooarchaeological material for paleoparasitological studies in Patagonia. Journal of Archaeological Sciences 38, 1511e1515. Beltrame, M.O., Sardella, N.H., Fugassa, M.H., Barberena, R., 2012. Paleoparasitological analysis of rodent coprolites from the archaeological site Cueva Huenul  rias do Instituto Oswaldo Cruz 107 (5), 1, Patagonia (Argentina). Memo 604e608. Beltrame, M.O., Fugassa, M.H., Baberena, R., Udrizar Sauthier, D.E., Sardella, N.H., 2013. New record of anoplocephalid eggs (Cestoda: Anoplocephalidae) collected from rodent coprolites from archaeological and paleontological sites of Patagonia, Argentina. Parasitology International 62, 431e434. Beltrame, M.O., Fugassa, M.H., Udrizar Sauthier, D.E., Sardella, N.H., 2014. Paleoparasitological study of rodent coprolites from “Los Altares” paleontological site, Patagonia, Argentina (in this issue). Quaternary International. Beveridge, I., 1994. Family Anoplocephalidae Cholodkovsky, 1902. In: Khalil, L.F., Jones, A., Bray, R.A. (Eds.), Key to the Cestode Parasites of Vertebrates. CAB International, Wallingford, pp. 315e366. Bouchet, F., Guidon, N., Dittmar, K., Harter, S., Ferreira, L.F., Chaves, S.M., Reinhard, K., Araújo, A., 2003. Parasite remains in archaeological sites. Memo rias do Instituto Oswaldo Cruz 98 (1), 47e52.

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